Allsopp RC , Farmer LK , Fryatt AG , Evans RJ .

British Heart Foundation , Wellcome Trust , FS/09/059/27972 British Heart Foundation , PG/11/64/28772 British Heart Foundation , BHF_FS/09/059/27972 British Heart Foundation , BHF_PG/11/64/28772 British Heart Foundation

	FIGURE 1. Partial agonist sensitivity at P2X1 and P2X2 extracellular loop chimeras. a, schematic representation of the P2X1 receptor (black), P2X2 receptor (gray), and receptor chimeras P2X1-2EXT and P2X2-1EXT generated by replacement of the entire extracellular loop. b, representative currents mediated by 3-s application (indicated by bar) of 100 μm ATP (black), α,β-meATP (red), AP5A (green), or BzATP (blue) to P2X1, P2X2, and chimeric receptors expressed in Xenopus oocytes. c, histogram summary showing the average peak current mediated by partial agonist application plotted as a percentage of maximum 100 μm ATP response. d, concentration-response curves (normalized to maximum ATP response) for ATP, α,β-meATP, BzATP, and AP5A at the P2X1, P2X1-2EXT, P2X2-1EXT, and P2X2 receptors. Dotted line represents concentration-response curves published previously (19, 41). *, p < 0.05; ***, p < 0.001 (n = 4–8). Error bars, S.E.
	FIGURE 2. Antagonist sensitivity tracks with the extracellular loop. a, schematic showing P2X1 (black), P2X2 (gray), and chimeras P2X1-2EXT and P2X2-1EXT. Representative current traces mediated by a 3-s application (indicated by bar) of an EC90 concentration of ATP (open circles) and ATP plus suramin (filled circles) were recorded from Xenopus oocytes. b, histogram summary showing percentage of control current when suramin was presuperfused and co-applied with ATP. Error bars, S.E. c, representative current traces in response to an EC90 concentration of ATP (open triangles) and ATP plus NF449 (filled triangles). d, inhibition curves showing the effects of NF449 on WT and chimeric receptors. *, p < 0.05; **, p < 0.01 (n = 3–6).
	FIGURE 3. PPADS sensitivity tracked with the extracellular loop. a, schematic showing P2X1 (black) and P2X2 (gray) and chimeras P2X1-2EXT and P2X2-1EXT. Representative current traces mediated by a 3-s application (indicated by bar) of an EC90 concentration of ATP (open squares) and ATP plus PPADS (filled squares) were recorded from Xenopus oocytes. b, histogram showing percentage current change when PPADS was co-applied with ATP. *, p < 0.05; **, p < 0.01; ***, p < 0.001 (n = 3–5). Error bars, S.E.
	FIGURE 4. Partial agonist sensitivity at P2X1 and P2X2 transmembrane domain chimeras. a, c, and e, schematic representations of TM reciprocal chimeras and representative currents mediated by 3-s application (indicated by bar) of 100 μm ATP (black open circles), AP5A (gray hatched circles), or BzATP (black filled circles). a, TM1 chimeras. c, TM2 chimeras. e, TM1 + 2 chimeras. b, d, and f, histogram summaries showing the average peak currents mediated by partial agonist application plotted as a percentage of maximum 100 μm ATP response. *, p < 0.05; **, p < 0.01; ***, p < 0.001 (n = 4–8). Error bars, S.E.
	FIGURE 5. Partial agonist sensitivity at P2X1 and P2X2 intracellular domain chimeras. a, c, e, and g, schematic representations of amino- and carboxyl-terminal reciprocal chimeras and representative currents mediated by 3-s application (indicated by bar) of 100 μm ATP (black open circles), AP5A (gray hatched circles), or BzATP (black filled circles). a, amino-terminal chimeras. c, amino-terminal chimera subdivisions. e, carboxyl-terminal chimers. g, amino- and carboxyl-terminal chimeras. b, d, f, and h, histogram summaries showing the average peak current mediated by partial agonist application plotted as a percentage of maximum 100 μm ATP response. *, p < 0.05; **, p < 0.01; ***, p < 0.001 (n = 4–8). Error bars, S.E.
	FIGURE 6. Carboxyl terminus contribution to recovery from desensitization. a, representative currents mediated by 3-s application (indicated by bar) of 100 μm ATP (black traces) and subsequent repeat application (time interval as indicated) resulting in approximately 50% recovery from desensitization compared with stable, reproducible, maximum ATP response. b, amino acid sequence line up showing the initial residues of the carboxyl-terminal section of P2X1 (top) and P2X2 (bottom). Mutations are based on the nonconserved amino acid residues within the Cβ region (shown in gray). c, histogram summary showing the time required in between successive, maximal, reproducible recordings (3-s 100 μm ATP applications) to achieve 50% recovery from desensitization. d, scatter plot showing the time to 50% recovery from desensitization after 3-s 100 μm ATP application versus time to 50% decay as measured over a 3-s or 20-s continuous 100 μm ATP application. *, p < 0.05; ***, p < 0.001 (n = 5–17). Error bars, S.E.
	FIGURE 7. Efficacy of partial agonists (compared with ATP) for WT and chimeric receptors shows no correlation with the time course of ATP-mediated currents. Efficacy of partial agonists AP5A (a) and BzATP (b) as a percentage of maximum ATP evoked response (100 μm ATP) versus the receptor time course to desensitization is shown. Time course is expressed as the time to 50% desensitization over 3-s ATP application, or percentage current remaining at the end of prolonged 20-s ATP application, for fast/slow desensitizing receptors, respectively (n = 5–17).
	FIGURE 8. Summary of effects of chimeras on partial agonist potency and efficacy. Replacement of different regions of the P2X1 receptor with those from the P2X2 receptor, and vice versa modified partial agonist action. Residues in the extracellular loop determine antagonist sensitivity. The TM regions are involved in control of both agonist sensitivity and efficacy. The amino terminus can regulate agonist efficacy independently of sensitivity, and the carboxyl terminus is involved in recovery of the receptor from the desensitized state.

Allsopp, Cysteine scanning mutagenesis (residues Glu52-Gly96) of the human P2X1 receptor for ATP: mapping agonist binding and channel gating. 2011, Pubmed, Xenbase

Allsopp, Cysteine scanning mutagenesis (residues Glu52-Gly96) of the human P2X1 receptor for ATP: mapping agonist binding and channel gating. 2011, Pubmed , Xenbase
Allsopp, The intracellular amino terminus plays a dominant role in desensitization of ATP-gated P2X receptor ion channels. 2011, Pubmed , Xenbase
Boué-Grabot, A protein kinase C site highly conserved in P2X subunits controls the desensitization kinetics of P2X(2) ATP-gated channels. 2000, Pubmed , Xenbase
Brake, New structural motif for ligand-gated ion channels defined by an ionotropic ATP receptor. 1994, Pubmed , Xenbase
Brändle, Desensitization of the P2X(2) receptor controlled by alternative splicing. 1997, Pubmed , Xenbase
Browne, New structure enlivens interest in P2X receptors. 2010, Pubmed
Buell, An antagonist-insensitive P2X receptor expressed in epithelia and brain. 1996, Pubmed
Burnstock, Pathophysiology and therapeutic potential of purinergic signaling. 2006, Pubmed
Cao, Thr339-to-serine substitution in rat P2X2 receptor second transmembrane domain causes constitutive opening and indicates a gating role for Lys308. 2007, Pubmed
Chaumont, Patch-clamp coordinated spectroscopy shows P2X2 receptor permeability dynamics require cytosolic domain rearrangements but not Panx-1 channels. 2008, Pubmed
Coddou, Activation and regulation of purinergic P2X receptor channels. 2011, Pubmed
Cook, Desensitization, recovery and Ca(2+)-dependent modulation of ATP-gated P2X receptors in nociceptors. 1997, Pubmed
DEL CASTILLO, Interaction at end-plate receptors between different choline derivatives. 1957, Pubmed
El-Ajouz, Molecular basis of selective antagonism of the P2X1 receptor for ATP by NF449 and suramin: contribution of basic amino acids in the cysteine-rich loop. 2012, Pubmed , Xenbase
Evans, Pharmacological characterization of heterologously expressed ATP-gated cation channels (P2x purinoceptors). 1995, Pubmed
Evans, Structural interpretation of P2X receptor mutagenesis studies on drug action. 2010, Pubmed
Garcia-Guzman, Characterization of recombinant human P2X4 receptor reveals pharmacological differences to the rat homologue. 1997, Pubmed , Xenbase
Haines, The first transmembrane domain of the P2X receptor subunit participates in the agonist-induced gating of the channel. 2001, Pubmed
Hattori, Molecular mechanism of ATP binding and ion channel activation in P2X receptors. 2012, Pubmed
He, Dependence of purinergic P2X receptor activity on ectodomain structure. 2003, Pubmed
Hülsmann, NF449, a novel picomolar potency antagonist at human P2X1 receptors. 2003, Pubmed , Xenbase
Jiang, Tightening of the ATP-binding sites induces the opening of P2X receptor channels. 2012, Pubmed
Jiang, Amino acid residues involved in gating identified in the first membrane-spanning domain of the rat P2X(2) receptor. 2001, Pubmed
Jin, Structural basis for partial agonist action at ionotropic glutamate receptors. 2003, Pubmed , Xenbase
Kawate, Crystal structure of the ATP-gated P2X(4) ion channel in the closed state. 2009, Pubmed
Lape, On the nature of partial agonism in the nicotinic receptor superfamily. 2008, Pubmed
Michel, Identification of regions of the P2X(7) receptor that contribute to human and rat species differences in antagonist effects. 2008, Pubmed
Nicke, A functional P2X7 splice variant with an alternative transmembrane domain 1 escapes gene inactivation in P2X7 knock-out mice. 2009, Pubmed , Xenbase
North, Molecular physiology of P2X receptors. 2002, Pubmed
Pratt, Use-dependent inhibition of P2X3 receptors by nanomolar agonist. 2005, Pubmed
Rettinger, Desensitization masks nanomolar potency of ATP for the P2X1 receptor. 2004, Pubmed , Xenbase
Rettinger, Activation and desensitization of the recombinant P2X1 receptor at nanomolar ATP concentrations. 2003, Pubmed , Xenbase
Roberts, ATP binding at human P2X1 receptors. Contribution of aromatic and basic amino acids revealed using mutagenesis and partial agonists. 2004, Pubmed , Xenbase
Schwarz, Alternative splicing of the N-terminal cytosolic and transmembrane domains of P2X7 controls gating of the ion channel by ADP-ribosylation. 2012, Pubmed
Sim, Ectodomain lysines and suramin block of P2X1 receptors. 2008, Pubmed
Stoop, Contribution of individual subunits to the multimeric P2X(2) receptor: estimates based on methanethiosulfonate block at T336C. 1999, Pubmed , Xenbase
Valera, A new class of ligand-gated ion channel defined by P2x receptor for extracellular ATP. 1994, Pubmed , Xenbase
Werner, Domains of P2X receptors involved in desensitization. 1996, Pubmed , Xenbase
Xu, Splice variants of the P2X7 receptor reveal differential agonist dependence and functional coupling with pannexin-1. 2012, Pubmed
Young, P2X receptors: dawn of the post-structure era. 2010, Pubmed
Young, Molecular shape, architecture, and size of P2X4 receptors determined using fluorescence resonance energy transfer and electron microscopy. 2008, Pubmed